Purification and Structural Characterization of the Central Hydrophobic Domain of Oleosin

doi:10.1074/jbc.M202721200

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Purification and Structural Characterization of the Central Hydrophobic Domain of Oleosin^*

Ming Li^§, Denis J. Murphy^¶, Ka-Ho K. Lee, Reginald Wilson^**, Linda J. Smith^**, David C. Clark^**, and Jao-Yiu Sung

From the Department of Medicine & Therapeutics, 9/F, Clinical Building, Prince of Wales Hospital, The Chinese University of Hong Kong, Shatin, New Territory, Hong Kong, ^¶ Cambridge Laboratory, John Innes Canter, Norwich NR4 7UH, United Kingdom, the Department of Anatomy, Chinese University of Hong Kong, Shatin, Hong Kong, and the ^** Institute of Food Research, Norwich Research Park, Norwich NR4 7UA, United Kingdom

Received for publication, March 20, 2002, and in revised form, July 10, 2002

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The oil bodies of rapeseeds contain a triacylglycerol matrix surrounded by a monolayer of phospholipids embedded with abundantstructural alkaline proteins termed oleosins and some other minorproteins. Oleosins are unusual proteins because they contain a70-80-residue uninterrupted nonpolar domain flanked by relativelypolar C- and N-terminal domains. Although the hydrophilic N-terminaldomain had been studied, the structural feature of the centralhydrophobic domain remains unclear due to its high hydrophobicity.In the present study, we reported the generation, purification,and characterization of a 9-kDa central hydrophobic domain fromrapeseed oleosin (19 kDa). The 9-kDa central hydrophobic domainwas produced by selectively degrading the N and C termini withenzymes and then purifying the digest by SDS-PAGE and electroelution.We have also reconstituted the central domain into liposomes andsynthetic oil bodies to determine the secondary structure of thedomain using CD and Fourier transform infrared (FTIR) spectroscopy.The spectra obtained from CD and FTIR were analyzed with referenceto structural information of the N-terminal domain and the full-lengthrapeseed oleosin. Both CD and FTIR analysis revealed that 50-63%of the domain was composed of $beta$ -sheet structure. Detailed analysisof the FTIR spectra indicated that 80% of the $beta$ -sheet structure,present in the central domain, was arranged in parallel to theintermolecular $beta$ -sheet structure. Therefore, interactions betweenadjacent oleosin proteins would give rise to a stable $beta$ -sheetstructure that would extend around the surface of the seed oilbodies stabilizing them in emulsion systems. The strategies usedin our present study are significant in that it could be generallyused to study difficult proteins with different independent structuraldomains, especially with long hydrophobicdomains.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Most eukaryotic organisms can either store or transport lipids in the form of small (0.2-2 µM) triacylglycerol-rich, sphericallipid bodies (1). The lipid oil body has a relatively simplestructure, made up of triacylglycerol, a phospholipid monolayer,and oleosin. However, its ontogeny is poorly understood. Storagelipids are found in the seeds of most higher plants. These aretypically present as triacylglycerol-containing bodies of 0.5-2µM diameter bound by a monomolecular phospholipid annulus intowhich is embedded a layer of specific amphipathic proteins, theoleosins (2-4). This storage oil serves as a carbon source andenergy reserve that is mobilized following seed germination. Insome plant species, such as rapeseed and sunflower, the seed oilcontent can be as high as 40-60% fresh weight, and oleosins constitute10-20% of the total seed protein (5). Oleosins were initiallydefined as seed-specific proteins, associated exclusively withthe surfaces of storage oil bodies in plants. The precise functionand structure of oleosins have still not been elucidated. It isbelieved that they are responsible for the maintenance of a populationof discrete small diameter oil bodies found in seed tissues, particularlyduring the dehydration process that accompanies seed maturationin most plant species (6, 7). In the absence of such stabilizingentities, the oil bodies would tend to coalesce during water removalto form an amorphous mass of lipid, which would have a very lowsurface area/volume ratio (8). This would severely impede theaction of the lipases in mobilizing storage lipids following seedgermination, because lipases are interfacial enzymes, whose activityis dependent on the available surface area of substrates (9).

Amino acid data derived from the studies of more than 40 different seed oleosins revealed that oleosin possesses a characteristiccentral hydrophobic domain containing ~70 uninterrupted and unchargedresidues. This is the longest hydrophobic domain that has yetbeen found in any naturally occurring proteins. The central hydrophobicdomain is flanked by relatively polar C-terminal and N-terminaldomains. These domains are very diverse in their amino acid compositions.Oleosins are amphipathic proteins but they do not behave likebilayer membrane proteins, because they are localized at a singlelipid/water interface between the triacylglycerol core of theoil body and the surrounding aqueous cytoplasm. Oleosins thereforehave some analogies with other interfacial or monolayer-associatedproteins, such as apolipoproteins, that are involved in lipidtransport of mammalian circulatory systems (1) and hydrophobinsfound in fungi (10). Oleosins appear to act as a natural emulsifyingand stabilizing agent at an oil/water interface. This suggestsa possible biotechnological application for oleosins in the stabilizationof emulsion systems, in industries such as food processing, pharmaceuticalmanufacture, and oil spillage treatment. In addition, oleosinshave recently been proposed as a carrier for the expression andpurification of recombinant pharmaceutical peptides and industrialenzymes (11, 12). Therefore, there is considerable interestin understanding the secondary structure of oleosin and how oleosininteracts with oilbodies.

We have studied previously (13) the secondary structure of a full-length 19-kDa oleosin protein from rapeseed. In addition,we have also examined a recombinant protein corresponding to the6-kDa polar N-terminal domain of sunflower oleosin (14). Thesestudies were performed using CD and Fourier transform infrared(FTIR)¹ spectroscopy. The emerging model for the structure of oleosinis that of a central hydrophobic domain (mostly made up of extended $beta$ -structure) probably embedded into the lipidic core of oil bodiesin vivo. However, the structure of the central domain remainsunclear due to difficulties involved in producing and purifyingthe central domain. We have tried to express this central domainin Escherichia coli, in yeast, and in cell-free translation systems.These attempts were unsuccessful because the central domain washighly hydrophobic and produced extremely low yields. In contrast,the secondary structures of the N-terminal and C-terminal domains,which flank the central domain, have now been established. Thesedomains contained more $alpha$ -helix and unordered structures that arelocated on the surface of oil bodies and may also extend out fromthe surface of the oil bodies (13, 14). Although most investigatorsaccept the general feature of this model, it has been suggestedthat the central hydrophobic domain could contain a hairpin loop.This loop is centered on three conserved proline residues thatform an anti-parallel $beta$ -sheet structure (3), rather than forminga single parallel $beta$ -sheet structure as proposed in our originalmodel (13). Furthermore, studies on safflower and sunfloweroil bodies have led some researchers to suggest that the centraldomain was composed of mainly $alpha$ -helices (15). However, thesemodels have not yet been verified by experimental evidence becauseit is difficult to produce and reconstitute pure central hydrophobicdomain ofoleosin.

Therefore, the aims of the present study are to generate and purify the central hydrophobic domain and to elucidate the secondarystructure of liposome or the oil bodies-reconstituted centraldomain by CD and FTIR. In many proteins that contain structurallydistinct regions, the different domains fold independently toform separate but linked units of the protein. Hence, the structureof individual protein domains may be studied in isolation to circumventsome substantial difficulties (16-18). This allows for the unequivocalassignment of particular structures to particular domains. Becauseoil bodies from rapeseed were difficult to purify to homogeneityand the oleosin obtained from these purified natural oil bodieswas always contaminated with other proteins as demonstrated bySDS-PAGE, the natural oil bodies were corrupted, and the intactoleosin protein was purified by SDS-PAGE coupled with electroeluting.This purified oleosin was used in subsequent reconstitution, selectiveenzyme digestion, and secondary structure determination in thisstudy. Equally importantly, the use of a reconstituted system,resembling as much as possible the in vivo system, allows forthe highest probability that proteins are folded into a nativeconformation. The results presented here show that the purifiedcentral hydrophobic domain is mostly made up of an extended parallel $beta$ -sheet with relatively minor amounts of anti-parallel structure.The significance of these findings for oleosin-oil body interactionsisdiscussed.

EXPERIMENTAL PROCEDURES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Materials

Oleosins were obtained from mature seeds of Brassica napus. The lipid L- $alpha$ -phosphatidylcholine type IX-E from egg yolk andtrioleoylglycerol were obtained from Sigma, as was protease K.All other chemicals were of analyticalgrade.

Purification of 19-kDa Oleosin

Oil body membrane proteins were purified from rapeseeds as described previously (13). An equal volume of 2× SDS sample bufferwas added to the resuspended oil body membrane proteins. The samplewas then boiled for 5 min, vortexed briefly, and loaded onto apreparative SDS-PAGE gel containing 12% acrylamide (19). Thegels were rinsed with double distilled H₂O, and a strip of thegel was cut with a razor for staining with Coomassie Blue R-250.Gel slices, containing the 19-kDa protein, were localized by Westernblotting, and the corresponding areas of the original gel wereexcised for electroelution. The eluting buffer consisted of 50mM Tris-HCl (pH 8.0), 100 mM NaCl, 1 mM CaCl₂, 0.2% SDS, and 1mM EDTA. The purity of the eluted oleosin was checked by analyticalSDS-PAGE (18, 19). The eluted 19-kDa oleosin was precipitatedby adding 2.5-3 volumes of ice-cold acetone and mixing thoroughly.The acetone/eluate mixture was allowed to precipitate for 2 hat $-$ 80 °C. The tubes were then centrifuged at 20,000 × g for 30min at 4 °C, the acetone supernatant poured off, and the tubesinverted to drain. The precipitate was then solubilized in 6 Mguanidine HCl, 0.1 M Tris-HCl buffer (pH 8.0), 1 mM dithiothreitol,and 1 mM EDTA. The dissolved protein sample was placed into adialysis tube and dialyzed against refolding buffer containing50 mM Tris-HCl (pH 8.0), 100 mM NaCl, 1 mM CaCl₂, 10 mM sodiumcholate, and 1 mM EDTA for 72 h. The buffer was changed 4 timesat 4 °C.

Reconstitution of 19-kDa Oleosin into Artificial Oil Bodies

Lipid films were prepared by drying 20 mg of phospholipids in chloroform under a stream of nitrogen, followed by lyophilizationovernight. Solvent-free phosphatidylcholine was solubilized ina small volume of sodium cholate made up in phosphate-bufferedsaline (PBS) (22). The preparation was mixed vigorously untila clear solution was obtained with a final phosphatidylcholineconcentration of 20 mg/ml. A greater than 4-fold excess (w/w)of sodium cholate was used to dissolve the phospholipid. The concentrationof cholate was confirmed to be above its critical micellar concentrationof 7 mM. The purified and refolded oleosin protein in refoldingbuffer and trioleoylglycerol was then added to produce a finalphospholipid/oil/polypeptide ratio by weight of 1:20:2. The solutionwas sonicated for 5 min to form a uniform suspension. The suspensionwas dialyzed against 5 changes of buffer (30 mM Tris-HCl (pH 7.4),1 mM EDTA) and followed by sonication for 5 min. The phospholipid/oil/proteinsuspension was then centrifuged for 30 min at 5,000 × g. The reconstitutedoil bodies were collected by floatation and washed in refoldingbuffer to remove oil-free proteins. Finally the oil bodies wereresuspended in 10% sucrose made up in 30 mM Tris-HCl (pH 7.4).The mixtures were again sonicated for 30 s and allowed to standfor 2 h. The reconstituted phospholipid-oil-oleosin complexeswere then analyzed by immunocytochemistry and FTIRspectroscopy.

Electron Microscopy

Reconstituted oil body preparations were resuspended in LMP-agarose. The preparation was fixed in glutaraldehyde and embeddedin LR white resin as described previously (21). Sections of100 nm thickness were cut on a MT6000 Ultramicrotome and mountedon to nickel grids (300 mesh). The grids were submersed for 40min in a solution of 150 mM NaO buffer, pH 7.0, 0.1% Triton X-100,and 0.1% BSA. The grids were then incubated with anti-oleosinpolyclonal rabbit antibodies (diluted 1:1000 in PBS buffer, 0.1%Triton X-100, and 0.1% BSA) for 1 h. The grids were washed 4 timesin PBS, 0.1% Triton X-100, and 0.1% BSA, and then incubated for1 h in goat anti-rabbit IgG conjugated with 12 nm colloidal goldparticles (diluted 1:40 with PBS, 0.1% Triton X-100, and 0.1%BSA). The grids were poststained for 15 min in 1% aqueous uranylacetate and 2 min in Reynold's lead citrate. The sections wereexamined on a Philips 400 transmission electronmicroscope.

Preparation of the Central Hydrophobic Domain of Oleosin

The rapeseed 9-kDa central domain was prepared by treating purified full-length 19-kDa rapeseed oleosin, reconstituted intophospholipid/oil bodies as described above, with 0.1 mg/ml proteinaseK for 4 h at 25 °C. This treatment resulted in the preferentialdigestion of the hydrophilic N- and C-terminal domains. The lipid-embeddedcentral domain was inaccessible to the protease (22, 23).The digested oil body samples were then centrifuged at 3000 ×g for 10 min, washed, and resuspended in 10% sucrose (preparedin Tris-HCl (pH 7.4)). The identity of the rapeseed central domainpolypeptide that remained trapped in the purified oil bodies wasverified by sequencing of the first 12 residues from its N terminus.The secondary structure of the central domain (trapped in oilbodies and produced by selective protease digestion) was determinedby FTIR, as dry films and in aqueous medium. The spectra for testsamples were compared with those obtained for pure oil (control)to identify the bands obtained from the central peptide. The centraldomain trapped in the oil bodies was recovered by depriving thepolypeptide of oil, and the recovered central domain was thenreconstituted into liposomes for the secondary structural determinationby CD (14, 20).

Circular Dichroism Spectroscopy

CD spectra were obtained using on a Jasco J-600A spectropolarimeter (wavelength range 260-185 nm), under constant nitrogenflush and using 1 mm cells at 20 °C. The data were recorded on-lineusing an IBM computer. The spectra presented are derived froman average of 4 scans recorded at 10 nm/min. Instrument sensitivityof ± 20 millidegrees full scale was routinely used, along witha 4-s time constant (24). The instrument was regularly calibratedusing ammonium D-10-camphorsulfonate (25) and D-pantolactone(26).

The complex solution contained liposome-reconstituted (0.1 mg/ml) purified central domain or 19-kDa oleosin. Base line wascorrected with phospholipid solutions in the absence of protein.The CD data were expressed as mean residue ellipticity (Q, degrees·cm²·mol¹). The molar ellipticities (Q) can be determined from Q = MRW·Q°/10J.C. MRW is the mean residue weight determined from analysis ofthe amino acid composition; Q° is the measured ellipticity indegrees; J is the light path in cm; and C is the protein concentrationin g/ml. Data, at appropriate intervals between 260 and 185 nm,were analyzed by standard linear combination methods. The principleof this technique involves fitting the experimental spectrum withthe basis spectra for secondary structure motifs by a least squarecurve-fitting method. The basis spectra were prepared from referencespectra obtained from soluble proteins with established three-dimensionalstructures, determined by x-ray crystallography. The referenceset of proteins used in the estimation of protein secondary structureby CD spectroscopy was further enlarged to 37 proteins using additionalpublished data (27-30). The fraction of secondary structure wascalculated using a program based on that of Chen et al. and Sreeramaet al. (27-32). The SELCON3 program, different reference sets,and related data files were adopted from the websites: lamar.colostate.edu/~sreeram/SELCON3(27, 30). In the self-consistent method (SELCON3) (33) thespectrum of the protein analyzed was compared with the structureof the reference protein having the CD spectrum most similar tothat of the protein analyzed to make an initial guess for theunknown secondary structure. The matrix equation relating theCD spectra to the secondary structure was solved by the singularvalue decomposition algorithm (34). In addition, this programreturned estimates for the fractions of $alpha$ -helix (regular $alpha$ -helix+ distorted $alpha$ -helix), $beta$ -sheet (regular $beta$ -strand + distorted $beta$ -strand), $beta$ -turn, and unordered secondary structuremotifs.

Fourier Transform Infrared Spectroscopic Studies

The FTIR spectra for the central domain of oleosin and intact 19-kDa oleosin (in either artificial oil bodies or liposomes)were measured at room temperature on a Bio-Rad FTS60 spectrometer,using a liquid nitrogen-cooled mercury cadmium telluride detector(resolution of 2 cm¹) and Win-IR software. Triangular apodization was employed. Thesamples were introduced to the spectrometer in solution form.A total of 1200 scans was collected for each spectrum to get areasonable signal/noise ratio. Difference spectra were obtainedby digitally subtracting solvent spectra and phospholipid/oilbody (containing no protein) spectra. Each sample solution wasdetermined in three batches. The individual spectrum of threedeterminations for each sample was obtained and averaged to producea single spectrum. The data were processed using GRAMS/32 (GalacticIndustries). Second derivative spectral analysis and Fourier self-deconvolutionwere used to locate the position of the overlapping componentsof the amide I band, to confirm band center frequencies and assignthem to different secondary structures. Secondary structure componentswere accomplished by least squares iteration. Gaussian band shapeswere assumed for the deconvoluted components. The amide bandsI (80% C=O stretch, near 1650.0 cm¹), II (60% N-H bend and 40% C-N stretch, near 1550.0 cm¹), and III (40% C-N stretch, 30% N-H bend, near 1300.0 cm¹) are normally used to study protein secondary structure. Identificationof particular frequencies with secondary structures was made byreference to spectra of homopolypeptides and proteins with primarily $alpha$ -helical or $beta$ -sheet structures and proteins with knownstructures.

Data analysis and band decomposition have been described previously (35-39). Briefly, for analysis of each component in thespectra, four parameters were considered as follows: band position,band height, bandwidth, and band shape. Deconvolution and derivatizationwere employed to resolve the number and position of componentbands. Initial heights were set at 90% of those of the originalspectrum for the bands in the center and the edges, and 70% ofthe original heights for the other bands (39). Bandwidth estimateswere obtained through derivative spectra, and the Gaussian componentswere used. The decomposition method assumes that the extinctioncoefficient is the same for the different structural components.Thus, intensities are proportional to the fraction of each secondarystructure. Curve fitting was performed in two steps. (i) The bandposition was fixed, allowing width and heights to approach finalvalues. (ii) Band positions were allowed to change. The fittingresults were further evaluated by overlapping the reconstitutedoverall curve on the original spectra and examining the residualobtained by subtracting the fitting from the original curves.The conformational assignments of amide I, II, and III bands usedin this study were as described previously (35, 36). Partialleast square and other multivariate statistical methods were appliedto FTIR protein structural analysis (40-43). The fractional secondarystructure contents of the test samples used for the calibrationof the partial least square analysis were tabulated from the outputof the DSSP program (44). The protein data bank entries wereused for fractional secondary structure contentcomputing.

$alpha$ -Helical Structure-- The amide I and III frequencies of $alpha$ -helical structures occur between 1650.0-1655.0 cm¹ and 1262.0-1300.0 cm¹ regions, respectively (35, 36, 46, 48).

$beta$ -Sheet Structures-- The assignments proposed by Chirgadze and co-workers (47-50) were followed. A strong band between 1612.0 and 1640.0 cm¹ and a weaker band at ~1685.0 cm¹ are commonly observed for $beta$ -sheet structure (48). Antiparallel $beta$ -sheet structure manifests components between 1612.0-1640.0 cm¹ and 1670.0-1690.0 cm¹ (weak) (48) and B₂ components around 1629.0 cm¹ (47) and have strong amide II bands between 1510.0 and 1530.0cm¹ (47). The parallel $beta$ -sheet structures have bands between 1626.0-1640.0cm¹. It also manifests a B₂ component around 1640.0 cm¹ and 1530.0-1550.0 cm¹ (47, 50). Amide III frequencies occur in the 1230.0-1245.0cm¹ region (45).

Intramolecular and Intermolecular $beta$ -Sheet Structures-- Intramolecular $beta$ -sheet structure occurs at 1635.0 cm¹ (51, 52). Intermolecular $beta$ -sheet structure was assigned to the bandsbetween 1693.0-1686.0 cm¹ and 1627.0 cm¹ (51, 52).

$beta$ -Turn Structures-- The amide I vibrations of the $beta$ -turn structures have been the subject of detailed study over the past decade. The assignmentsused here were adopted from Pelton (48), Goormaghtigh (49),Renugopalakrishnan (53), Lagant et al. (54, 55), Seaton(56), and Ishizaki et al. (57). $beta$ -Turn structures were assignedto bands between 1655.0-1675.0 cm¹ and 1680.0-1696.0 cm¹. The type II $beta$ -turn structures occur around 1654.0, 1662.0, 1684.0,and 1255.0 cm¹. Type III $beta$ -turn structures occur at 1658.0, 1630.0, 1541.9,and 1277.0 cm¹. In addition, the band at 1660.0-1663.0 cm¹ (normally assigned to turn structures) is often found to reflectthe presence of some helical or irregularstructures.

Unordered Structures-- Although it is difficult to assign a particular sub-region of the amide I region to unordered structures, unordered structureis generally assigned to the band near 1640.0-1651.0 cm¹ in the IR (48). The 1654.0-1657.0 cm¹ region appears to characterize unordered structure on the basisof IR studies of feather keratin and denatured proteins (58).

The characteristic vibrations for a protein containing mixed domains of extensive $beta$ -turn and less extensive $beta$ -sheet structures,from well established $beta$ -sheet vibrations and newly established $beta$ -turn vibrations, are expected to occur at 1670.0-1680.0 andaround 1240.0 cm¹ (57).

RESULTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Purification of Full-length Oleosin Protein

Oleosin proteins are relatively abundant in rapeseed, constituting 8-20% of the total seed protein (13, 14). Therefore,mature rapeseeds were used to produce the full-length 19-kDa oleosinprotein in our study. Rapeseed oil bodies are difficult to purifyto homogeneity and are always contaminated with other proteins.In fact, when we used the proteins obtained from thoroughly washedand purified natural oil bodies, there were always more than 4protein bands present in our SDS-PAGE. Hence, we used purified19-kDa oleosin and reconstituted the protein into liposomes orsynthetic oil bodies instead of using natural intact oil bodies.Oleosin contains highly hydrophobic domain, and once removed fromoil bodies, they tend to aggregate in the absence of solubilizingdetergents. Purification of full-length rapeseed oleosin was attainedby preparative SDS-PAGE on gradient gels containing 10-18% acrylamide,followed by electroelution. The purity of the 19-kDa rapeseedoleosin is shown in Fig. 1A. The results show that a small amountof dimeric 19-kDa oleosin is always present at the level of the40-kDa protein marker. There was also a trace of a putative trimerat 60 kDa. These bands were formed by oligomers of the 19-kDaoleosin because (a) the sample originated from a single 19-kDaband excised from an SDS-PAGE gel, and (b) the 40- and 60-kDabands were recognized by antibodies specific to the 19-kDa oleosin(results not shown). The purified 19-kDa oleosin protein was completelydenatured by adding 6 M guanidine hydrochloride and then refoldedby dialyzing against refolding buffer. The appearance of the CDand FTIR spectra indicates that oleosin has a well ordered proteinstructures. Good structural consistence among different repeatsof the refolding processes as assayed by CD and FTIR methods indicatesthat the polypeptides were refolded into ordered structures.

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Fig. 1. Polypeptide profile of purified full-length and central domain oleosin preparations separated on 12% acrylamide gels as described under "Experimental Procedures." A, molecular mass markers of 10.5, 14.2, 18, 24, 29, 36, and 48 kDa; B, purified full-length 19-kDa oleosin (note dimmer at about 40 kDa); C, 9-kDa central domain prepared by proteinase K digestion of oil body reconstituted 19-kDa oleosin.

Reconstitution of Oleosins into Artificial Oil Bodies

In the absence of oleosin, newly synthesized phospholipid/trioleoylglycerol oil bodies were found to be unstable in 10% sucrose,50 mM Tris-HCl (pH 7.4). Within a matter of a few minutes, theoil bodies aggregated to form an amorphous lipidic mass. In contrast,suspensions containing oleosin-phospholipid-trioleoylglyceroloil body complex were stable and maintained turbidity for morethan 10 h at 4 °C. This reconstituted artificial oleosin-oil bodycomplex contained a population of spherical oil bodies with sizesranging from about 0.4 to 1.6 µM, which is similar to the sizeof native oil bodies in vivo (Fig. 2A). However, oil bodies containingonly the central domain of oleosin were almost as unstable asoil bodies containing no protein. This was demonstrated by a decreasein turbidity of the reconstituted oil body suspensions and byelectron microscopy (Fig. 2B). These data indicate that stabilityof oleosin/oil body emulsion is not conferred by one protein domainalone. Rather, it is through the interaction of several domains,both within and between oleosin molecules, that enables them tomaintain the integrity of the oil body during prolonged storage.The reconstituted oil body preparations were examined immunohistochemically.Antibodies specific against the 19-kDa rapeseed oleosin was usedto detect the reconstituted oleosin. It was found that the 19-kDaoleosins were localized on the surface of the reconstituted oilbodies, as indicated by the dark spots around the surface of theartificial oil body (Fig. 2, C and D). It was also demonstratedthat the antigen sites of 19-kDa oleosin were in the sequencesof N/C-terminal domains (the hydrophilic regions).

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Fig. 2. Ultrastructure of phospholipid/triacylglycerol suspensions in aqueous solution following storage in the presence and absence of full-length and central domain oleosin proteins. A, oil bodies reconstituted with purified full-length rapeseed oleosin protein were stable for >10 h as emulsions of droplet size 0.1-0.5 µM. B, oil bodies reconstituted with only the oleosin 9-kDa central domain were almost as unstable as those containing no added protein. The initial oil droplets were relatively small (0.2-0.6 µM) and irregular, and these soon coalesced into the kind of amorphous mass as seen in B. No dark spots could be detected by immunostaining with specific antibodies against 19-kDa rapeseed oleosin. C, full-length rapeseed oleosin protein-reconstituted oil bodies were immunostained with specific antibodies against 19-kDa rapeseed oleosin. The dark spots (arrow) around the surface of the artificial oil body were an indication of reconstituted 19-kDa oleosins. The dark spots (arrow) between the space of the artificial oil bodies indicate the reconstituted 19-kDa oleosins. It is also demonstrated that the antigen sites of 19-kDa oleosin are within the sequences of N/C-terminal domains.

The 9-kDa central domain was prepared from its full-length oleosin as described under "Experimental Procedures." The purityof the 9-kDa central domain is shown in Fig. 1. The preparationwas more than 95% pure, with only minute traces of the uncleaved19-kDa oleosin. The structure of the 9-kDa polypeptide, trappedin the oil bodies, was studied by FTIR. The recovered 9-kDa centraldomain was also deprived of oil, dissolved in 6 M guanidine hydrochloride,and reconstituted into liposomes. The structure of the liposomereconstituted 9-kDa central domain was studied by CD. The CD andFTIR spectra suggested that the central domain has a well orderedprotein structure. The structural consistency among differentrepeats of the process indicated that the polypeptide folded intoorderedstructures.

Estimation of Secondary Structure Content by CD

Attempts to obtain CD spectra from reconstituted oleosin/oil body were unsuccessful due to the turbidity of the solution.Therefore, the CD spectra of liposome-reconstituted central domain(Fig. 3) were plotted against the spectra from liposome-reconstitutedN-terminal domain (14) and the full-length protein (13). ACD spectra set of reference proteins, with the number of proteinsvarying from 15 to 37 and having a good representation of $alpha$ -rich, $beta$ -rich, and mixed $alpha$ $beta$ proteins, has been used in secondary structureanalysis (27-30). Analysis of the experimental spectra was conductedbetween 260 and 185 nm at 1-nm intervals. The variable selectionprocedure as used in the self-consistent method yielded a setof solutions as the number of reference proteins and the numberof singular value decomposition components were varied. Four selectioncriteria (sum rule, fraction rule, spectral rule, and helix rule)(59) were used to identify valid solutions among the solutionsgiven by the self-consistent method. The CD spectrum of the centraldomain reconstituted into liposomes was found to be differentfrom the N-terminal domain (14) and the full-length protein(13). It showed a relatively low level of $alpha$ -structure and amuch higher level of $beta$ -structure. The intensity of the negativebands in the spectra of the central domain was too weak for thepolypeptide to contain more than 15% $alpha$ -helix. All of these spectrawere relatively well structured. The structural consistency amongdifferent repeats was high indicating that the reconstituted centraldomain was renatured successfully. The central domain was foundto contain 45-55% $beta$ -sheet structure, 20% $beta$ -turn structure, andonly 5-9% $alpha$ -helical structure (Table I). In contrast, the reconstitutedN-terminal domain contained approximately only 24% $beta$ -sheet and22% $beta$ -turn structure plus 17% $alpha$ -helix and 37% unordered structure(14). The reconstituted intact 19-kDa oleosin contained 42% $beta$ -sheet, 20% $beta$ -turn structure, and 18% $alpha$ -helix. The results indicatedthat ~70% of the $beta$ -sheet structure in the intact 19-kDa oleosinare located in the central domain.

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Fig. 3. Far UV and CD spectra of liposome-reconstituted central domain ( $black-triangle$ ) of oleosin and the spectra of full-length oleosin ( $black-square$ ) and N-terminal domain () for comparison. Reconstitution procedures are described under "Experimental Procedures." The symbols are to assist in curve identification and do not represent individual data points. In comparison with the spectra from intact 19-kDa oleosin or N-terminal domain, the spectrum of the central domain showed relatively lower levels of $alpha$ -structure and much higher levels of $beta$ -structure, and the intensity of the negative bands in the spectrum was too weak for the polypeptide to contain more than 15% $alpha$ -helix.

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Table I
Fractional secondary structure contents as derived from CD and FTIR of central domain of oleosin reconstituted into liposomes and artificial oil bodies

Conformational Assignments of Components from FTIR Spectra of Reconstituted Central Domain and Intact 19-kDa Oleosin in Oil Bodies

Full Range Spectra-- The full range deconvolution FTIR spectra (1,000-1,800 cm¹) for reconstituted rapeseed oleosin central domain and intact 19-kDaoleosin are shown in Fig. 4, A and B. The corresponding spectrumfor the reconstituted sunflower N-terminal domain has been publishedpreviously (14).

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Fig. 4. Infrared Fourier self-deconvolution full range spectra of central domain (A) of oleosin and intact 19-kDa oleosin (B) reconstituted into phospholipid/triaglycerol oil bodies. C and D are the expanded spectra of amide I and II region of A and B. For central domain (A and C), the peaks at 1616.0, 1627.2, 1640.0, 1523.5, 1534.0, and 1551.0 cm¹ are indicative of $beta$ -sheet structure. The shoulder at 1686.2 and the peak at 1627.2 cm¹ indicate the presence of intermolecular $beta$ -sheet structure. The peaks at 1627.2, 1640.0, and 1551.0 cm¹ and shoulder at 1534.0 cm¹ are indicative of parallel $beta$ -sheet structure. For the intact 19-kDa oleosin (B and D), the peaks at 1650.0, 1278.5, and 1300.0 cm¹ are indicative of $alpha$ -helical structures and probably overlapped unordered structures. The peaks at 1616.5 and 1634.0 cm¹ and a shoulder at 1692.0 cm¹ are indicative of $beta$ -sheet structure. The shoulder at 1692.0 and the peaks at 1634.0, 1536.5, and 1557.0 cm¹ indicate the presence of parallel $beta$ -sheet structure and intermolecular $beta$ -sheet structure. The peaks at 1616.5 and 1511.5 cm¹ are indicative of anti-parallel $beta$ -sheet structure, overlapped with tyrosine absorption.

Central Domain-- The main amide I peaks of the central domain occurred at 1616.0, 1627.2, 1640.0, 1653.0, and 1673.5 cm¹, with shoulder at 1686.2 cm¹ (Fig. 4, A and C). The main amide II peaks were found at 1523.5,1534.0, 1551.0, and 1580.5 cm¹, together with a smaller peak at 1512.0 and 1566.0 cm¹. The main amide III peak occurred at 1251.9 cm¹ and a small peak at 1268.7 cm¹. The peaks at 1616.0, 1627.2, 1640.0, 1523.5, 1534.0, and 1551.0cm¹ and the shoulder at 1686.2 cm¹ are indicative of $beta$ -sheet structure. The peak at 1653.0 cm¹ is probably unordered structure, overlapped with type I or III, $beta$ -turn, or $alpha$ -helical structures. This is because there is oftenoverlap of $alpha$ -helical absorption with that of random coil and typeI and III $beta$ -turn structures. The shoulder at 1686.2 cm¹ and the peak at 1627.2 cm¹ indicates the presence of intermolecular $beta$ -sheet structure, forminga protein oligomer shell (52, 53). The peaks at 1627.2, 1640.0,and 1551.0 cm¹ and shoulder at 1534.0 cm¹ are indicative of parallel $beta$ -sheet structure. The peaks at 1616.0and 1512.0 cm¹ are indicative of anti-parallel $beta$ -strand structure, overlappedwith tyrosine absorption. The presence of intermolecular and parallel $beta$ -sheet structures infers that the central domain of oleosin formsa protein oligomer shell to stabilize plant triglyceride droplets.The secondary structure contents of the reconstituted centraldomain, determined by FTIR analysis, was found to be similar tocalculations derived from the CD analysis. In both cases, themajor component is $beta$ -sheet structure, which is estimated to contribute63% (FTIR data) to 50% (from CD data), of the total central domain,with a very minor 5-7% $alpha$ -helical structure. The 63% of $beta$ -sheetstructure, determined by FTIR, can be further subdivided into51% parallel with intermolecular $beta$ -sheet structure and 12% anti-parallelstructures.

Full-length 19-kDa Oleosin-- The main amide I peaks for the full-length 19-kDa oleosin occurred at 1616.5, 1634.0, and 1650.0 cm¹, with shoulders at 1670.0, 1680.5, and 1692.0 cm¹ (Fig. 4, B and D). The main amide II peaks occurred at 1511.5,1522.5, 1547.0, and 1584.0 cm¹, together with a shoulder at 1536.5 cm¹. The main amide III peak was found at 1254.5 cm¹ with small peaks at 1278.5 and 1300.0 cm¹. The peaks at 1650.0, 1278.5, and 1300.0 cm¹ were indicative of $alpha$ -helical structures probably overlapped withunordered structures. The peaks at 1616.5 and 1634.0 cm¹ and a shoulder at 1692.0 cm¹ were indicative of $beta$ -sheet structure. The shoulder at 1692.0and the peaks at 1634.0, 1536.5, and 1557.0 cm¹ indicate the presence of parallel and intermolecular $beta$ -sheetstructures, forming a protein oligomer shell (60, 61). Thepeaks at 1616.5 and 1511.5 cm¹ were indicative of anti-parallel $beta$ -strand structure, overlappedwith tyrosine absorption. The presence of parallel and intermolecular $beta$ -sheet structures strongly suggests that the full-length 19-kDaoleosin formed a protein oligomer shell in its reconstituted form.The structural contents of the reconstituted 19-kDa oleosin, ascalculated from the FTIR spectra, were similar to calculationsderived from CD analysis. $beta$ -Sheet structures were determined tobe the major component (48%) of the 19-kDa oleosin. The remainderwas made up of 16% $alpha$ -helical, 15% $beta$ -turn, and 21% unorderedstructures.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The oleosin molecule, based on its primary amino acid sequence, can be divided into three distinct structural domains as follows:(a) a relatively polar N-terminal domain containing about 50 residues;(b) a central hydrophobic domain with about 75 residues; and (c)a polar/amphipathic C-terminal domain with about 65 residues (13,14). To date, the protein sequence of more than 40 seed-specificoleosins, from different plant species, have been described. Thesestudies revealed that all oleosins have a similar domain structure.In particular, they share a highly conserved hydrophobic centraldomain containing about 75 residues, flanked by relatively polar/amphipathicN- and C-terminal domains. These terminal domains are quite variablein length and composition (2, 3, 63). Indeed, it has beenshown recently (64) that the 19-kDa rapeseed oleosin proteincan be engineered to contain an additional C-terminal polypeptide( $beta$ -glucuronidase, 68 kDa) to create a chimeric 87-kDa fusion protein.In transgenic plants expressing this recombinant fusion protein,the protein is able to associate with oil bodies and stabilizethem in the same manner as unmodified 19-kDaoleosin.

Previous physical studies (13, 14) in our laboratory, using FTIR and CD spectroscopy, have indicated that the three major19-kDa oleosin isoforms purified from rapeseed each contain 40-50% $beta$ -sheet structures. The finding agrees with predictions of thesecondary structure based on the primary sequences of the protein(64). These predictions indicate that the central hydrophobicdomain, which makes up ~40% of the total protein, is likely tobe composed of mostly $beta$ -sheet structure. It is possible that thishydrophobic $beta$ -sheet is extended in a linear conformation, whichwill allow it to interact with neighboring oleosin molecules toform oligomeric $beta$ -sheet structures. Indeed, analogous oligomericassociations have been found in other interfacial amphipathicproteins, such as the fungal hydrophobins (10). Alternatively,the hydrophobic central domain may contain a hairpin loop formedaround three conserved proline residues. This allows the linear $beta$ -sheet to double back upon itself to form an anti-parallel $beta$ -sheetstructure (3). This would extend from the surface deep intothe hydrophobic interior of the oil bodies. Previous studies havenot been able to differentiate between these twoalternatives.

In order to resolve the finer structures of the central domain of oleosin, it is necessary to reconstitute the purified centraldomain preparations into oil bodies resembling as closely as possiblethose in vivo. The examination and comparison of the secondarystructures of the full-length oleosin and the N-terminal and centraldomains serve two purposes. First, it reveals the interactionbetween the various domains and the oil bodies and their physicalbehavior (e.g. the stability of the resultant emulsions). Second,the analysis of discrete protein domains allows for a more definiteassignment of particular secondary structures to a given domainthan is possible when an entire protein is analyzed. Our resultsindicate that maximum stability of reconstituted oil body emulsionsis only possible with the intact oleosin protein. Once the N-and C-terminal domains were removed by protease digestion, theresulting rapeseed 9-kDa central domain was a relatively pooremulsifying and stabilizing agent. This suggests that the surface-oriented,amphipathic N- and C-terminal domains may play an important rolein emulsionformation.

The data presented in this study indicated that when the peripheral N- and C-terminal domains of the rapeseed oleosin wereremoved, the residual 9-kDa central hydrophobic domain that remainedcontained 50-63% $beta$ -sheet structure. This 9-kDa polypeptide containedthe entire 75-residue hydrophobic domain (strongly predicted tobe $beta$ -structure), plus about 15 residues of the amphipathic C-terminaldomain (predicted to be $alpha$ -helical) (63). Detailed analysis ofthe FTIR spectra allows us to identify the existence of intermolecular $beta$ -sheet structure and to distinguish between the parallel andanti-parallel types of $beta$ -sheet structure, using assignments describedpreviously (47-49, 60, 61). This shows that, of the 63% total $beta$ -sheet structure determined by FTIR spectroscopy, some 51% werearranged in parallel with intermolecular $beta$ -sheet structure, andonly 12% were anti-parallel. Therefore, the three universallyconserved proline residues, found within the "proline knot" motifof the oleosin central domain, were not likely to be importantfor determining the topology of oleosin as predicted previously(3). It has been reported from other studies (66) that whenthe three proline residues were substituted by leucine, the prolineknot was required for oil body targeting and was less importantfor determining the topology of the central domain. It was alsopossible that a small part (~12%) of the anti-parallel $beta$ -sheetstructure, a hairpin loop formed around three conserved prolineresidues, is contained in the hydrophobic centraldomain.

Our findings make it difficult to reconcile with speculations that virtually the entire central domain is structured as a"hairpin loop," composed mainly of anti-parallel $beta$ -sheet structure(3). In addition, the entire central domain that forms hairpinloop should not contain intermolecular $beta$ -sheet structure (3).The proposed heterodimers formed by oleosins (63, 67, 68)are more likely to be stabilized by the association of parallel $beta$ -sheets to form a $beta$ -sheet structure. In a hairpin loop structure,most of the hydrogen bond-forming potential of the protein wouldbe satisfied via anti-parallel $beta$ -sheet. This would make the formationof dimers and intermolecular $beta$ -sheet structure less likely. Wehave commented previously on the tendency for purified oleosinsto self-associate to form dimers, trimers, and higher order oligomers(13). Presently, we confirmed the existence of the dimeric andtrimeric forms of oleosin. Such self-associations have also beenobserved when a single oleosin isoform from soybean was expressedin transgenic rapeseed plants.² Hence, identical oleosin molecules can interact to form homo-oligomers,some of which remain associated even in the presence of strongdenaturants, such as SDS. This indicates that oleosins, both invitro and in vivo, can self-associate. We propose that this occursvia hydrogen bonding between the adjacent parallel $beta$ -sheet foundin the uncharged central domain. This would form a tightly knitted $beta$ -sheet structure that would extend around the entire surfaceof the oil body, forming a proteinaceous cage that encapsulatesand stabilizes the storage lipidswithin.

Our results also indicated that maximum stability of reconstituted oil body emulsions was only attained by reconstitutionof the intact oleosin with oil bodies. The 9-kDa central domainwas a relatively poor emulsifying and stabilizing agent. The surface-orientedN- and C-terminal domains play an important role in emulsion formation.It is also likely that N- and C-terminal domains can associatewith each other to form dimers, trimers, or oligomers, which wouldform a tightly knitted amphipathic structure extending aroundthe entire surface of the oil body. The amphipathic nature ofN- and C-terminal domains together with the central domain wouldform a proteinaceous cage that stabilizes the storage lipids within.This is required for the maintenance of a population of discretesmall-diameter oilbodies.

FOOTNOTES

^* The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

^§ To whom correspondence should be addressed. Tel.: 852-26323023; Fax: 852-26373852; E-mail: b976711@mailserv.cuhk.edu.hk.

Present address: DMV International, NCB-Laan 80, PO Box 13, 5460 BA Vegnel, TheNetherlands.

Published, JBC Papers in Press, July 17, 2002, DOI 10.1074/jbc.M202721200

² C. Sarmiento, E. Herman, and D. J. Murphy, unpublishedresults.

ABBREVIATIONS

The abbreviations used are: FTIR, Fourier transform infrared; BSA, bovine serum albumin; PBS, phosphate-buffered saline.

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Purification and Structural Characterization of the Central Hydrophobic Domain of Oleosin*

Purification and Structural Characterization of the Central Hydrophobic Domain of Oleosin^*